EP2003259A2 - Building brick - Google Patents

Abstract

The brick consists of two essentially parallel side walls joined by two outer transverse bridge elements (5) and at least one cross-bridge (6) with cavities (7) formed between the cross-bridge and bridge elements, especially for accommodating thermally insulating material (8). At least one bridge element is a double bridge with at least two bridges (10,11), whereby the bridges are joined by at least one cross-rib (12).

Description

The invention relates to a brick consisting of two mutually spaced and substantially parallel side walls, which are interconnected via two outer, side surfaces forming web elements and at least one transverse web, wherein between the transverse web and each a web element cavities for receiving a heat-insulating material are formed.

Such bricks are known from the prior art. For example, this describes DE 102 29 856 A1 a high-hole thermal insulation stone with rock-high, large-sized, at right angles to the bearing joint standing high holes that are filled with heat-insulating materials. In addition, the high-hole thermal insulation stone on smaller high holes, which are arranged between rows of larger high holes and in which no heat-insulating substances are used. The smaller high holes are arranged in rows, wherein the outside arranged high holes are formed open to the side surface.

In addition, bricks are known that are used with concrete or mortar filling as sound insulation stones. However, these sound insulation stones are characterized by either significantly higher manufacturing costs or by a too low strength, so that they are used exclusively for the family house. Since such sound insulation stones have a very low thermal resistance, they are not suitable for the construction of an outer wall or additionally require a thermal insulation composite system, which is applied to the outer surface of the outer wall.

Based on this prior art, the invention has the object, a brick in such a way that on the one hand has sufficient mechanical strength, so that it can also be used in multi-storey housing and he also has a high thermal resistance, so that the brick addition can be used to build an outer wall of a building.

The solution of this problem provides in a generic brick that at least one web element is designed as a double web with at least two webs, wherein the webs are connected to each other via at least one transverse rib.

The design of the web element as a double web has the advantage that the brick in particular in the area of the web elements has a high strength, which improves its load capacity, so that the brick is not only useful in single-family, but also in multi-storey housing. In addition, the embodiment of the brick according to the invention with thermal insulation material is advantageous in that a high heat transfer resistance can be achieved. In this way, if necessary, a thermal insulation composite system in the outer facade area can be dispensed with or such a composite thermal insulation system leads to a further improvement of the heat transfer resistance, which ultimately leads to the creation of an economical building, which is characterized by a low energy requirement per unit area.

The brick according to the invention represents a high-strength shuttering stone, for example, fired clay, which is always made of the same thickness with high thermal insulation, and sound-absorbing packing. As a result, a significant rationalization effect is achieved in the production of such bricks. The high stability is achieved according to the invention by a double-walled design of the outer web element or the outer web elements of the brick and by an above-average breaking strength, which leads to a classification of the brick according to the invention in at least the Steinfestigkeitsklasse 8. In addition, the brick according to the invention has a high Longitudinal compressive strength and thus earthquake capability. By prefabricated insulation bricks can be made with high thermal resistance at relatively low production costs.

The insulation elements can be designed optimized either with regard to the thermal insulation or in terms of sound insulation. Likewise, an unprecedented combination of both properties can be achieved simultaneously. With an intended bulk density of the casing stone material or of the brick shards of preferably below 1.6 kg / dm ³ , an equivalent thermal conductivity of ≦ 0.10 W / m ² K can be achieved with a suitable filling material.

In a further feature of the invention it is provided that a plurality of identically formed channels are arranged between the two webs of the double web, between each of which a transverse rib is arranged. The identically formed channels can serve on the one hand the air duct. Several transverse ribs significantly improve the mechanical strength of the brick.

It is provided according to a further feature of the invention that both web elements are designed as double webs identical.

The channels are preferably formed at their ends with extensions that simplify, for example, a slit of the double web in this area, so that in particular cables, but also other power lines in this area can be inserted into the channels through a correspondingly formed slot without the Stability of the brick is significantly reduced.

Preferably, the extensions of the channels are each aligned with the outer web of the double web, so that the herauszunehmende to form a slot material of the brick is low.

According to a further feature of the invention, it is provided that the outer web of the double web has in its outer surface recesses which extend substantially parallel to the longitudinal axis direction of the cavities. These recesses serve as starting points or insertion lines for the insertion of slots, wherein the recesses simplify the preparation of slots forming machines and in Moreover, the recesses indicate the optimum location of corresponding slots in the bricks. The arrangement of the recesses is chosen such that in the composite arranged bricks have a total of the height of the wall continuous recesses. Accordingly, the recesses are preferably arranged distributed symmetrically over the corresponding surface of the double web.

According to a further feature of the invention it is provided that the recesses are arranged in the region of the channels, wherein it has proven to be advantageous to arrange the recesses in the region of the extensions of the channels, so that still in the region of the recesses of the outer web of the double web standing material is formed comparatively thin, so that the slitting of the brick in this area is possible into the recess with little effort. Nevertheless, the brick retains due to the double-walled design of the double bridge the required strength, which makes it possible to use the brick according to the invention also in multi-storey housing.

The recesses are formed in cross-section substantially semicircular. The same applies to the extensions, which are also preferably formed in the cross section substantially semicircular. Such recesses or extensions can be produced in a simple manner.

According to a further feature of the invention, it is provided that the oppositely disposed side walls of the brick have in their outer surfaces corresponding toothing elements, in particular in the form of spring and groove.

The bricks invention thus solves in a special way a problem of chamber-like bricks in terms of their slittability. Usually known from the prior art bricks lose considerably by the slitting and milling of the outer surface of mechanical strength. The reason for this is that brick-like built bricks change their bearing behavior significantly by a running over the entire surface of the brick slot. This problem is eliminated in the brick according to the invention by the design of the web element as a double web, since only the outer web of the web member is slotted and the brick retains its carrying behavior despite its chamber-like structure.

Therefore, it is also possible in the brick according to the invention in the course of improved applicability to form the slots usually consisting of rows of holes by recessed line-shaped slots.

Another essential aspect of the structural behavior of a brick according to the invention is the absorbable edge pressure of the brick. This edge pressure plays an important role especially for single loads and here for example in ceiling supports. Due to an indispensable deflection of a ceiling, the ceiling is not flat on the masonry, consisting of corresponding bricks on. Rather, the ceiling loads one edge of the bricks much stronger. Chamber-like bricks in this respect have the disadvantage that the outer web of the brick as a result of Knicktragverhaltens no increased corner stresses and thus can absorb loads. This problem is also solved by the brick according to the invention with the web member formed as a double web, since the web members are aligned with the double web to the outer surfaces of a wall made of the bricks.

According to a further feature of the invention, it is provided that the brick is characterized by a ratio of side wall surfaces, web element surfaces and transverse land surfaces to Füllkörperflächen, each based on the total footprint of the brick from 1 to 2.2 to 1 to 2.5.

Furthermore, it is additionally provided that the brick is characterized by a ratio of longitudinally extending surfaces of the contact surface to the transverse to the longitudinal direction surfaces of the contact surfaces of 1 to 2 to 1 to 2.3, wherein the filler surfaces are not taken into account.

Due to these special geometry ratios of the brick this is significantly improved in its mechanical load capacity.

The preparation of corresponding thermally insulated bricks can be rationalized that the thermal insulation materials used in the cavities are formed as a body, which are divided according to the hole geometry of the brick in the ratio of 2: 1, so that every second body of thermal insulation material is exactly half like the prefabricated thermal insulation elements. This leads to a efficient and waste-free production with high efficiency, since, for example, each row of cavities has two such cavities, of which one cavity has twice the length of the second cavity.

In the previously known bricks, it was customary to anchor the insulating elements in the cavities of the brick to produce a necessary mechanical bond of the insulating elements with the brick. For this purpose, it is known to provide a subsequent hardening of the thermal insulation material, to bond the thermal insulation material in the cavity, to use an additional binder or to expand the thermal insulation material by adding heat or by an exothermic process. Alternatively, a mechanical solidification of the thermal insulation material, in particular a heat-insulating element is provided in a cavity of the brick, namely the configuration of a groove and a spring or a spring-wedge connection.

An improvement of the brick can be achieved that the flat in the surface walls of the cavities are made specifically with a specifically defined surface roughness. This surface roughness of the wall of the cavities leads to an increase of, for example, up to 1 mm. Advantageously, in particular punctiform or interrupted formed linear supports, resulting in a three-dimensional clamping of the heat-insulating element in the cavity. This surface roughness or the punctiform or linear holders can be produced in a targeted manner by means of a surface treatment by means of drag cores having a specific surface structure.

The above-described embodiments between the wall of the cavity and the thermal insulation material, in particular a thermal insulation element with linear cavities in stone height leads to air circulation or to a high mechanical sensitivity of the bricks in the region of the transition to the insulating material. This disadvantage is inventively eliminated in that the cavities are closed over the entire surface with a lid, which consists for example of a mortar. This cover prevents both convection within a wall formed from the bricks and also provides mechanical protection and weather protection of the bricks and disposed therein thermal insulation material on the site.

Fig. 1

einen Mauerstein in einer Draufsicht;

Fig. 2

den Mauerstein aus Fig. 1 in einer Draufsicht und

Fig. 3

einen Abschnitt einer Wand, bestehend aus mehreren Mauersteinen gemäß Fig. 1 und 2.

Further features and advantages of the invention will become apparent from the following description of the accompanying drawings, in which a preferred embodiment of the invention is shown. In the drawing show:

Fig. 1

a brick in a top view;

Fig. 2

the brick Fig. 1 in a plan view and

Fig. 3

a section of a wall consisting of several bricks according to Fig. 1 and 2 ,

The FIGS. 1 and 2 show a brick 1, which consists of two mutually spaced and parallel to each other extending side walls 2, 3, which are connected via two outer side surfaces 4 forming web elements 5 and three transverse webs 6 together. Between the transverse webs 6 and the web elements 5 on the one hand and adjacent transverse webs 6 on the other hand cavities 7 are formed, are used in the thermal insulation elements 8, for example, mineral fibers.

Between each web element 5 and the adjacently arranged transverse web 6 or between adjacently arranged transverse webs 6 two cavities 7 are arranged in a row, wherein the cavities 7 a row are separated by a rib 9 from each other. The ribs 9 therefore extend at right angles to the transverse webs 6.

It can be seen that each row of cavities 7 consists of a longer and a shorter cavity 7, wherein the shorter cavity 7 has half the length of the longer cavity 7. The cavities 7 of adjacent rows are arranged alternately, so that the ribs 9 of adjacent rows of cavities 7 are arranged offset to one another.

Each web element 5 is formed as a double web with two webs 10, 11, wherein the webs 10, 11 are connected to each other via transverse ribs 12.

Between the two webs 10, 11 of the double web a plurality of identically formed channels 13 are arranged, between each of which a transverse rib 12 is arranged. The Channels 13 extend over the entire height of the brick 1, as is the case for the cavities 7.

At their ends, the channels 13 have extensions 14, which are semicircular in cross section. The extensions 14 extend from the channels 13 in the direction of the side surface 4 and are arranged at the ends of the channels 13.

It can also be seen that the outer web 10 of the double web in its outer surface, namely the side surface 4 of the brick 1 has recesses 15 which are aligned substantially parallel to the longitudinal axis direction of the cavities 7 extending and which are semicircular in cross section. The recesses 15 correspond in shape and size substantially to the extensions 14 and are arranged opposite the extensions 14, so that the web 10 is formed between the recesses 15 and the extensions 14 with a reduced material thickness.

From the FIGS. 1 and 2 Finally, it can be seen that the brick 1 in the region of its side wall 2 has a projection in the form of a spring 16 and in the region of its side wall 3 a correspondingly shaped recess in the form of a groove 17, spring 16 and groove 17 forming toothed elements 16, 17, with which adjacently arranged bricks 1 are interlinked.

Fig. 3 shows the arrangement of three bricks 1 in the composite and it can be seen that the recesses 15 of the stacked bricks 1 are aligned, so that the recesses 15 can be used to arrange continuous power lines, such as cables. In addition, the recesses 15 can be slotted continuously to the extensions 14, without thereby the brick 1 is substantially impaired in its mechanical strength. In this case, power lines, such as cables can also be introduced into the channels 13.

LIST OF REFERENCE NUMBERS

1

brick

2

Side wall

3

Side wall

4

side surface

5

web element

6

crosspiece

7

cavity

8th

thermal insulation element

9

rib

10

web

11

web

12

transverse rib

13

channel

14

extension

15

recess

16

feather

17

groove

Claims (15)

Brick consisting of two mutually spaced and substantially parallel side walls (2, 3), the two outer side surfaces (4) forming web elements (5) and at least one transverse web (6) are interconnected, wherein between the transverse web ( 6) and in each case one web element (5) cavities (7), in particular for receiving a thermal insulation material (8) are formed,
characterized,
in that at least one web element (5) is designed as a double web with at least two webs (10, 11), wherein the webs (10, 11) are connected to one another via an at least one transverse rib (12). Brick according to claim 1,
characterized,
that between the two webs (10, 11) of the double web a plurality of identically formed channels (13) are arranged, between each of which a transverse rib (12) is arranged. Brick according to claim 1,
characterized,
that both web elements (5) are identical as a double web. Brick according to claim 2,
characterized,
that the channels (13) are formed at their ends with extensions (14). Brick according to claim 4,
characterized,
that the extensions (14) each for the outer web (10, 11) of the double web are aligned. Brick according to claim 1,
characterized,
that the outer web (10) of the double web in its outer surface (4) has recesses (15) extending parallel to the longitudinal direction of the cavities (7) substantially. Brick according to claims 2 and 6,
characterized,
that the recesses (15) are arranged in the region of the channels (13). Brick according to claims 4 and 6,
characterized,
that the recesses (15) in the region of the extensions (14) of the channels (13) are arranged. Brick according to claim 6,
characterized,
that the recesses (15) are semicircular in cross-section substantially. Brick according to claim 4,
characterized,
that the extensions (14) are semicircular in cross-section substantially. Brick according to claim 1,
characterized,
that the oppositely arranged side walls having (2, 3) in their outer surfaces corresponding toothing elements (16, 17), in particular in the form of spring (16) and groove (17). Brick according to claim 1,
marked by
a fracture resistance at least of the stone strength class 8. Brick according to claim 1,
marked by
a gross density of the brick shard of ≤ 1.8 kg / dm ³ and a thermal conductivity ≤ 0.12 W / m ² K. Brick according to claim 1,
marked by
a ratio of side wall surfaces, web element surfaces and transverse web surfaces to filler surfaces, in each case based on the contact surface, of 1 to 2.2 to 1 to 2.5. Brick according to claim 1,
marked by
a ratio of longitudinally extending surfaces of the footprint to transverse to the longitudinal direction surfaces of the footprint, each without regard to the packing area, from 1 to 2 to 1 to 2.3.

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